use sys::component::{self, Component};
use sys::disk::Disk;
use sys::processor::*;
use sys::users::get_users;
use std::cell::UnsafeCell;
use std::collections::HashMap;
use std::mem::{size_of, zeroed};
use std::time::SystemTime;
use LoadAvg;
use Networks;
use Pid;
use ProcessExt;
use RefreshKind;
use SystemExt;
use User;
use windows::process::{
compute_cpu_usage, get_handle, get_system_computation_time, update_disk_usage, update_memory,
Process,
};
use windows::tools::*;
use ntapi::ntexapi::{
NtQuerySystemInformation, SystemProcessInformation, SYSTEM_PROCESS_INFORMATION,
};
use winapi::shared::minwindef::FALSE;
use winapi::shared::ntdef::{PVOID, ULONG};
use winapi::shared::ntstatus::STATUS_INFO_LENGTH_MISMATCH;
use winapi::um::minwinbase::STILL_ACTIVE;
use winapi::um::processthreadsapi::GetExitCodeProcess;
use winapi::um::sysinfoapi::{GetTickCount64, GlobalMemoryStatusEx, MEMORYSTATUSEX};
use winapi::um::winnt::HANDLE;
use rayon::prelude::*;
pub struct System {
process_list: HashMap<usize, Process>,
mem_total: u64,
mem_free: u64,
swap_total: u64,
swap_free: u64,
global_processor: Processor,
processors: Vec<Processor>,
components: Vec<Component>,
disks: Vec<Disk>,
query: Option<Query>,
networks: Networks,
boot_time: u64,
users: Vec<User>,
}
struct Wrap<T>(T);
unsafe impl<T> Send for Wrap<T> {}
unsafe impl<T> Sync for Wrap<T> {}
unsafe fn boot_time() -> u64 {
match SystemTime::now().duration_since(SystemTime::UNIX_EPOCH) {
Ok(n) => n.as_secs() - GetTickCount64() / 1000,
Err(_e) => {
sysinfo_debug!("Failed to compute boot time: {:?}", _e);
0
}
}
}
impl SystemExt for System {
#[allow(non_snake_case)]
fn new_with_specifics(refreshes: RefreshKind) -> System {
let (processors, vendor_id, brand) = init_processors();
let mut s = System {
process_list: HashMap::with_capacity(500),
mem_total: 0,
mem_free: 0,
swap_total: 0,
swap_free: 0,
global_processor: Processor::new_with_values("Total CPU", vendor_id, brand, 0),
processors,
components: Vec::new(),
disks: Vec::with_capacity(2),
query: Query::new(),
networks: Networks::new(),
boot_time: unsafe { boot_time() },
users: Vec::new(),
};
if let Some(ref mut query) = s.query {
let x = unsafe { load_symbols() };
if let Some(processor_trans) = get_translation(&"Processor".to_owned(), &x) {
let proc_time_trans = get_translation(&"% Processor Time".to_owned(), &x);
if let Some(ref proc_time_trans) = proc_time_trans {
add_counter(
format!("\\{}(_Total)\\{}", processor_trans, proc_time_trans),
query,
get_key_used(&mut s.global_processor),
"tot_0".to_owned(),
);
}
for (pos, proc_) in s.processors.iter_mut().enumerate() {
if let Some(ref proc_time_trans) = proc_time_trans {
add_counter(
format!("\\{}({})\\{}", processor_trans, pos, proc_time_trans),
query,
get_key_used(proc_),
format!("{}_0", pos),
);
}
}
} else {
sysinfo_debug!("failed to get `Processor` translation");
}
}
s.refresh_specifics(refreshes);
s
}
fn refresh_cpu(&mut self) {
if let Some(ref mut query) = self.query {
query.refresh();
let mut used_time = None;
if let &mut Some(ref key_used) = get_key_used(&mut self.global_processor) {
used_time = Some(
query
.get(&key_used.unique_id)
.expect("global_key_idle disappeared"),
);
}
if let Some(used_time) = used_time {
self.global_processor.set_cpu_usage(used_time);
}
for p in self.processors.iter_mut() {
let mut used_time = None;
if let &mut Some(ref key_used) = get_key_used(p) {
used_time = Some(
query
.get(&key_used.unique_id)
.expect("key_used disappeared"),
);
}
if let Some(used_time) = used_time {
p.set_cpu_usage(used_time);
}
}
}
}
fn refresh_memory(&mut self) {
unsafe {
let mut mem_info: MEMORYSTATUSEX = zeroed();
mem_info.dwLength = size_of::<MEMORYSTATUSEX>() as u32;
GlobalMemoryStatusEx(&mut mem_info);
self.mem_total = auto_cast!(mem_info.ullTotalPhys, u64);
self.mem_free = auto_cast!(mem_info.ullAvailPhys, u64);
}
}
fn refresh_components_list(&mut self) {
self.components = component::get_components();
}
fn refresh_process(&mut self, pid: Pid) -> bool {
if self.process_list.contains_key(&pid) {
if refresh_existing_process(self, pid) == false {
self.process_list.remove(&pid);
return false;
}
true
} else if let Some(mut p) = Process::new_from_pid(pid) {
let system_time = get_system_computation_time();
compute_cpu_usage(&mut p, self.processors.len() as u64, system_time);
update_disk_usage(&mut p);
self.process_list.insert(pid, p);
true
} else {
false
}
}
#[allow(clippy::cast_ptr_alignment)]
fn refresh_processes(&mut self) {
let mut buffer_size: usize = 512 * 1024;
loop {
let mut process_information: Vec<u8> = Vec::with_capacity(buffer_size);
let mut cb_needed = 0;
let ntstatus = unsafe {
process_information.set_len(buffer_size);
NtQuerySystemInformation(
SystemProcessInformation,
process_information.as_mut_ptr() as PVOID,
buffer_size as ULONG,
&mut cb_needed,
)
};
if ntstatus != STATUS_INFO_LENGTH_MISMATCH {
if ntstatus < 0 {
sysinfo_debug!(
"Couldn't get process infos: NtQuerySystemInformation returned {}",
ntstatus
);
}
let mut process_ids = Vec::with_capacity(500);
let mut process_information_offset = 0;
loop {
let p = unsafe {
process_information
.as_ptr()
.offset(process_information_offset)
as *const SYSTEM_PROCESS_INFORMATION
};
let pi = unsafe { &*p };
process_ids.push(Wrap(p));
if pi.NextEntryOffset == 0 {
break;
}
process_information_offset += pi.NextEntryOffset as isize;
}
let nb_processors = self.processors.len() as u64;
let process_list = Wrap(UnsafeCell::new(&mut self.process_list));
let system_time = get_system_computation_time();
let processes = process_ids
.into_par_iter()
.filter_map(|pi| unsafe {
let pi = *pi.0;
let pid = pi.UniqueProcessId as usize;
if let Some(proc_) = (*process_list.0.get()).get_mut(&pid) {
proc_.memory = (pi.WorkingSetSize as u64) >> 10u64;
proc_.virtual_memory = (pi.VirtualSize as u64) >> 10u64;
compute_cpu_usage(proc_, nb_processors, system_time);
update_disk_usage(proc_);
proc_.updated = true;
return None;
}
let name = get_process_name(&pi, pid);
let mut p = Process::new_full(
pid,
if pi.InheritedFromUniqueProcessId as usize != 0 {
Some(pi.InheritedFromUniqueProcessId as usize)
} else {
None
},
(pi.WorkingSetSize as u64) >> 10u64,
(pi.VirtualSize as u64) >> 10u64,
name,
);
compute_cpu_usage(&mut p, nb_processors, system_time);
update_disk_usage(&mut p);
Some(p)
})
.collect::<Vec<_>>();
self.process_list.retain(|_, v| {
let x = v.updated;
v.updated = false;
x
});
for p in processes.into_iter() {
self.process_list.insert(p.pid(), p);
}
break;
}
if cb_needed == 0 {
buffer_size *= 2;
continue;
}
buffer_size = (cb_needed + (1024 * 10)) as usize;
}
}
fn refresh_disks_list(&mut self) {
self.disks = unsafe { get_disks() };
}
fn refresh_users_list(&mut self) {
self.users = unsafe { get_users() };
}
fn get_processes(&self) -> &HashMap<Pid, Process> {
&self.process_list
}
fn get_process(&self, pid: Pid) -> Option<&Process> {
self.process_list.get(&(pid as usize))
}
fn get_global_processor_info(&self) -> &Processor {
&self.global_processor
}
fn get_processors(&self) -> &[Processor] {
&self.processors
}
fn get_total_memory(&self) -> u64 {
self.mem_total >> 10
}
fn get_free_memory(&self) -> u64 {
self.mem_free >> 10
}
fn get_used_memory(&self) -> u64 {
(self.mem_total - self.mem_free) >> 10
}
fn get_total_swap(&self) -> u64 {
self.swap_total >> 10
}
fn get_free_swap(&self) -> u64 {
self.swap_free >> 10
}
fn get_used_swap(&self) -> u64 {
(self.swap_total - self.swap_free) >> 10
}
fn get_components(&self) -> &[Component] {
&self.components
}
fn get_components_mut(&mut self) -> &mut [Component] {
&mut self.components
}
fn get_disks(&self) -> &[Disk] {
&self.disks
}
fn get_disks_mut(&mut self) -> &mut [Disk] {
&mut self.disks
}
fn get_users(&self) -> &[User] {
&self.users
}
fn get_networks(&self) -> &Networks {
&self.networks
}
fn get_networks_mut(&mut self) -> &mut Networks {
&mut self.networks
}
fn get_uptime(&self) -> u64 {
unsafe { GetTickCount64() / 1000 }
}
fn get_boot_time(&self) -> u64 {
self.boot_time
}
fn get_load_average(&self) -> LoadAvg {
get_load_average()
}
}
impl Default for System {
fn default() -> System {
System::new()
}
}
fn is_proc_running(handle: HANDLE) -> bool {
let mut exit_code = 0;
let ret = unsafe { GetExitCodeProcess(handle, &mut exit_code) };
!(ret == FALSE || exit_code != STILL_ACTIVE)
}
fn refresh_existing_process(s: &mut System, pid: Pid) -> bool {
if let Some(ref mut entry) = s.process_list.get_mut(&(pid as usize)) {
if !is_proc_running(get_handle(entry)) {
return false;
}
update_memory(entry);
update_disk_usage(entry);
compute_cpu_usage(
entry,
s.processors.len() as u64,
get_system_computation_time(),
);
true
} else {
false
}
}
pub(crate) fn get_process_name(process: &SYSTEM_PROCESS_INFORMATION, process_id: usize) -> String {
let name = &process.ImageName;
if name.Buffer.is_null() {
match process_id {
0 => "Idle".to_owned(),
4 => "System".to_owned(),
_ => format!("<no name> Process {}", process_id),
}
} else {
let slice = unsafe {
std::slice::from_raw_parts(
name.Buffer,
name.Length as usize / std::mem::size_of::<u16>(),
)
};
String::from_utf16_lossy(slice)
}
}